Comparing device for employment in a record card collator or like machine



Dec. 27, 1960 H. s. BEATTIE ET AL 2,966,660

COMPARING DEVICE FOR EMPLOYMENT IN A RECORD CARD COLLATOR 0R LIKE MACHINE Onginal Filed Feb. 4, 1954 15 Sheets-Sheet 1 1 ||J E 12. u w n a m m m H m n u L N W MM m ||v||||| 1 I SEL a: APP wk :SEQ E5128 M 8 w FIIIIJ $2205 29 @885; :2: 55 CGE 55 .521 h H II n u Tam a n Dec. 27, 1960 H. s. BEATTIE ETAL 2,966,660 COMPARING DEVICE FOR EMPLOYMENT IN A RECORD CARD COLLATOR OR LIKE MACHINE Original Filed Feb. 4, 1954 15 Sheets-Sheet 2 SIPA TO COMPARER CIRCUIT L TERMINAL IC TO COMPARER crRcuIT L2 TERMINAL 3c PW1 TO A. c. ERASE SOURCE L3 INVENTORS HORACE S. BEATTIE By RALPH E. PAGE RALPH L. PALMER ATTORNEY Dec. 27, 1960 H. s. BEATTI DEVI E FOR E CARD COLLAT Onginal Filed Feb. 4, 1954 E ET AL 2,966,660 MPLOYMEN C T IN A RECORD OR OR LIKE MACHINE l5 Sheets-Sheet 5 COMPAR IN G ON X mn ON x mn ON x owm 23th M331 El 0mm 23E, wm SQ En.

uwm 23E. mm Sm Em W W W BEATTIE PAGE RALPH L. PALMER A ORNEY N INVENTORS W252? BY I H. s. BEATTIE ET AL 2,966,660 COMPARING DEVICE FOR EMPLOYMENT IN A RECORD HINE CARD COLLATOR OR LIKE MAC Original Filed Feb. 4, 1954 15 Sheets-Sheet 6 FIG.4C

INVHVTORS HORACE S. BEATTIE RALPH Ew PAGE BY RALPH L. PALMER Dec. 27, 1960 H. s. BEATTIE ETAL 2,966,660 COMPARING DEVICE FOR EMPLOYMENT IN A RECORD CARD COLLATOR OR LIKE MACHINE Original Filed Feb. 4. 1954 15 Sheets-Sheet 7 FIG. 45 FIG. 4F

(3% Tmov S) Ja-soov 50 T 03 FIG. 46 FIG. 4H

INVENTORS HORACE s. BEATTIE RALPH E. PAGE BY RALPH L PALMER ATTORNEY 8 0 m e m 6 S 6 a 9 m 2 e D h R s O 5 m 1 R M L m mM am wm m T R wo A R mm E L mw mn emu N09 I 1 m P 4 w C b e F d e 1 i F m n i g l r 0 Dec. 2 7, 1960 FIG.6B

INVENTORS HORACE s BEATTIE RALPH E, PAGE BY RALPH L. PALMER A/ firm A ORNEY Dec. 27, 1960 BEATTIE ET AL 2,966,660

H. S. COMPARING DEVICE FOR EMPLOYMENT IN A RECORD CARD COLLATOR OR LIKE MACHINE Original Filed Feb. 4, 1954 15 Sheets-Sheet 9 INVENTORS HORACE S. BEATTIE RALPH E. PAGE BY RALPH L. PALMER MTLB TTORNEY Dec. 27, 1960 H. s. BEATTIE Er AL 2,966,660 COMPARING DEVICE FOR EMPLOYMENT IN A RECORD CARD COLLATOR OR LIKE MACHINE Original Filed Feb. 4, 1954 15 Sheets-Sheet 10 EXAMPLE N0. 1

READ- IN TIME "Y" [N VEN TORS HORACE S. BEATTIE BY RALPH E. PAGE RALPH L. PALMER TTORN EY 1960 H. s. BEATTIE EI'AL 2,966,660

COMPARING DEVICE FOR EMPLOYMENT IN A RECORD CARD COLLATOR OR LIKE MACHINE Original Filed Feb. 4, 1954 15 Sheets-Sheet 11 FIG. 66

FIG.5G

FIG. 6H

FIG. 5H

64 THROUGH 72: MACHINE TIME INVHVTORS HORACE BEATTIE PH al PH L PAGE PALMER TTORNEY Dec. 27, 1960 H. s. BEATTIE ETAL 2,966,660

COMPARING DEVICE FOR EMPLOYMENT IN A RECORD CARD COLLATOR OR LIKE MACHINE A Original Filed Feb. 4, 1954 15 Sheets-Sheet 12 FIG. 61

FIG. SI

INVENTORS HORACE S. BEATTIE By RALPH E. PAGE RALPH L PALMER 4421 M TORNEY Dec. 27, 1960 H. s. BEATTIE ET AL 2,966,650

COMPARING DEVICE FOR EMPLOYMENT IN A RECORD CARD COLLATQR OR LIKE MACHINE Original Filed Feb. 4, 1954 15 Sheets-Sheet 1:5

EXAMPLE NO. 4

INVENTORS HORACE S. BEATTI b, M ATTORNEY Dec. 27, 1960 s, BEATTlE ETAL 2,966,660

COMPARING DEVICE FOR EMPLOYMENT IN A RECORD CARD COLLATOR OR LIKE MACHINE Original Filed FBI). 4, 1954 15 Sheets-Sheet 14 STEEL INVENTORS HORACE 5. 55mm: RALPH e PAGE BY RALPH PALMER TTORNEY Dec. 27, 1 H s BEATTIE El 2 966 660 A COMPARING DEVICE FOR EMPLOYMENTLIN A RECORD CARD COLLATOR 0R LIKE MACHINE origmal Filed Feb. 4. 1954 15 Sheets-Sheet 15 EXAMPLE No.5 1 1.20 MACHINE TIME INVENTORS HORACE s. BEATTIE RALPH E. PAGE BY RALPH L. PALMER 2,966,660 Patented Dec. 27, 1960 2,966,660 COMPARING DEVICE FOR EMPLOYMENT IN A RECORD CARD COLLATOR OR LIKE MACHINE Horace S. Beattie, Poughkeepsie, Ralph E. Page, Lagrangeville, and Ralph L. Palmer, Poughkeepsie, N.Y., assignors to International Business Machines Corporation, New York, N.Y., a corporation of New York Original application Feb. 4, 1954, Ser. No. 408,132,

now Patent No. 2,939,110, dated May 31, 1960. Divided and this application Oct. 9, 1959, Ser. No. 851,209

13 Claims. (Cl. 340-172.5)

This application is a divisional application of Serial No. 408,132, now US. Patent No. 2,939,110, filed February 4, 1954.

This invention relates to a comparing device and more particularly to a comparing device which may be used in a record card controlled machine. The record card controlled machine may be of the type generally known in the art as a record card collator.

The following United States patents each disclose a record controlled machine generally of the collator type: No. 2,359,670 granted to R.E. Page on October 3, 1944; No. 2,379,828 granted to D. W. Rubidge et al. on July 3, 1945; No. 2,602,544 granted to B. E. Phelps et al. on July 8, 1952; and No. 2,602,545 granted to H. P. Luhn et al. on July 8, 1952.

The comparing device disclosed hereinafter will indicate the relative order as between a first series of pulse groups and a synchronized second series of pulse groups. The first Series of pulse groups may be formed by simultaneously reading a plurality of columns of a first or primary record card and storing this information serially by column on a first magnetic track and then reading the information from said first magnetic track in serial by column order. The second series of pulse groups may be formed by simultaneously reading a plurality of columns of a second or secondary record card and storing this information serially by column on a second magnetic track and then reading the information from said second magnetic track in serial by column order. The readings from said first and second magnetic tracks are synchronized.

The pulse groups to be compared may be read respectively from magnetic drum storage units, a first or primary drum serving as a first source of pulse groups and a second or secondary drum, synchronized with respect to said first drum, serving as a second source of pulse groups.

The primary object of the invention is to provide a simple comparing device capable of fast accurate operation.

A second object of the invention is to provide a comparing circuit which has a small number of components and is easy and economical to produce.

A further object of the invention is a comparing device which is readily adaptable for use with multiple deck record cards generally of the type disclosed in United States Patent No. 2,602,545, issued to H. P. Luhn et al. on July 8, 1952, and in United States patent application Ser. No. 346,976 of John F. Coleman, filed on April 6, 1953, now Patent No. 2,750,113.

Yet another object of the present invention is to provide a compact comparing device which has a wide degree of utility.

A still further object of the invention is a comparing device having increased capacity.

An additional object of the invention is an electronic comparing circuit which consists of a minimum number of components and is fast and accurate in operation.

An additional object of the invention is a novel method for serially storing the information obtained from a record card, and subsequently serially reading said information.

Other objects of the invention will be pointed out in the following description and claims and illustrated in the accompanying drawings, which disclose, by way of examples, the principle of the invention and the best mode, which has been contemplated, of applying that principle.

In the drawings:

Fig. l is a schematic diagram disclosing a first source of pulse groups and a second source of pulse groups connected to a comparer circuit of the type disclosed in detail in Fig. 3.

Fig. 2 schematically discloses means for reading in formation from a primary record card and magnetic means for serially storing and subsequently serially reproducing the information read from said primary record card. Fig. 2 also discloses means for reading information from a secondary record card and for serially storing and subsequently serially reproducing the information read from said secondary record card.

Fig. 2A is a timing chart of the complete machine, i.e., including the read-in time. read-out time, reset time, and erase time, as labelled in Fig. 2A.

Fig. 3 is a detailed circuit diagram of the comparer circuit shown in block form in Fig. 1. The comparer circuit of Fig. 3 is also used in combination with the apparatus shown in Fig. 2. The detailed circuits of the blocks shown in Fig. 3 are set forth in the figures enumerated hereinafter.

Fig. 3A is a detailed timing chart of read-out time of the novel comparing device disclosed herein. Read-out time is approximately through 152.7 machine time as seen from Fig. 2A.

Fig. 3B is a detailed timed showing of the primary pulse train and secondary pulse train of each of the examples (1 through 8) of operation of the novel comparing device. Fig. 3B is to be read in conjunction with the readout timing chart of Fig. 3A.

Fig. 4A is a detailed circuit diagram of the amplifiers represented by blocks 202p, 204p, 202s and 204s in the comparer circuit of Fig. 3.

Fig. 4B is a detailed circuit diagram of the electronic switches represented by blocks 206p and 206s in the comparer circuit of Fig. 3.

Fig. 4C is a detailed circuit diagram of the inverter switches represented by blocks 208p, 210p, 221p, 208s, 210s and 221s in the comparer circuit of Fig. 3.

Fig. 4D is a detailed circuit diagram of the comparer switches represented by blocks 213p and 213s in the comparer circuit of Fig. 3.

Fig. 4E is a detailed circuit diagram of the electronic switches represented by blocks 223p and 223s in the comparer circuit of Fig. 3.

Fig. 4F is a detailed circuit diagram of the electronic switches represented by blocks 227p and 227s in the comparer circuit of Fig. 3.

Fig. 4G is a detailed circuit diagram of the trigger circuits represented by blocks 216p, 225p, 216s and 225s in the comparer circuit of Fig. 3.

Fig. 4H is a detailed circuit diagram of the thyratron switches represented by blocks 219p and 219s in the comparer circuit of Fig. 3.

Fig. 5A is a simplified showing of primary magnetic track PT at read-in time "5 under the conditions of Example No. 1.

Fig. 5B is a simplified showing of primary magnetic track PT at read-in time 3 under the conditions of EX- ample No. 1.

Fig. 5C is a simplified showing of primary magnetic 3 track PT at read'in time 1" under the conditions of Example No. 1. i

Fig. 5D is a simplified showing of primary magnetic track PT at read-in time under the conditions of Example No. 1.

Fig. B is a simplified showing of primary magnetic track PT at read-in time Z under the conditions of Example No. l.

Fig. SP is a simplified showing of primary magnetic track PT at read-in time Y under the conditions of Example No. 1.

Fig. 5G is a simplified showing of primary magnetic track PT at read-in time X under the conditions of Example No. 1. I

Fig. 51-1 is a simplified showing of primary magnetic track PT at read-in time 64 through 72 machine time, under the conditions of Example No. l.

Fig. SI is a simplified showing of primary magnetic track PT at (read-out time) approximately 120 machine time under the conditions of Example No. 1.

Fig. 6A is a simplified showing of secondary magnetic track ST at read-in time 5 under the conditions of Example No. 1.

Fig. 6B is a simplified showing of secondary magnetic track ST at read-in time 3" under the conditions of Example No. 1.

Fig. 6C is a simplified showing of secondary magnetic track ST at read-in time 1" under the conditions of Example No. 1.

Fig. 6D is a simplified showing of secondary magnetic track ST at read-in time "0" under the conditions of Example No. 1.

Fig. 6E is a simplified showing of secondary magnetic track ST at read-in time Z under the conditions of Example No. 1.

Fig. 6F is a simplified showing of secondary magnetic track ST at read-in time Y under the conditions of Example No. 1.

Fig. 6G is a simplified showing of secondary magnetic track ST at read-in time X" under the conditions of Example No. 1.

Fig. 6H is a simplified showing of secondary magnetic track ST at read-in time 64 through 72 machine time under the conditions of Example No. 1.

Fig. 6I is a simplified showing of secondary magnetic track ST at approximately (read-out time) 120' machine time under the conditions of Example No. 1.

Fig. 7 is a simplified showing of primary magnetic track PT at (read-out time) approximately 120 machine time under the conditions of Example No. 2.

Fig. 8 is a simplified showing of secondary magnetic track ST at (read-out time) approximately 120 machine time under the conditions of Example No. 2.

Fig. 9 is a simplified showing of primary magnetic track PT at (read-out time) approximately 120 machine time under the conditions of Example No. 3.

Fig. 10 is a simplified showing of secondary magnetic track ST at (read-out time) approximately 120 machine time under the conditions of Example No. 3.

Fig. 11 is a simplified showing of primary magnetic track PT at (read-out time) approximately 120 machine time under the conditions of Example No. 4.

Fig. 12 is a simplified showing of secondary magnetic track ST at (read-out time) approximately 120 machine time under the conditions of Example No. 4.

Fig. 13 is a simplified showing of primary magnetic track PT at (read-out time) approximately 120 machine time under the conditions of Example No. 5.

Fig. 14 is a simplified showing of secondary magnetic track ST at (read-out time) approximately 120 machine time under the conditions of Example No. 5.

Fig. 15 is a simplified showing of primary magnetic track PT at (read-out time) approximately 120 machine time under the conditions of Example No. 6.

Fig. 16 is a simplified showing of secondary magnetic track ST at (read-out time) approximately machine time under the conditions of Example No. 6.

Fig. 17 is a simplified showing of primary magnetic track PT at (read-out time) approximately 120 machine time under the conditions of Example No. 7.

Fig. 18 is a simplified showing of secondary magnetic track ST at (read-out time) approximately 120 machine time under the conditions of Example No. 7.

Fig. 19 is a simplified showing of primary magnetic track PT at (read-out time) approximately 120" machine time under the conditions of Example No. 8.

Fig. 20 is a simplfied showing of secondary magnetic track ST at (read-out time) approximately 120 machine time under the conditions of Example No. 8.

Referring to Fig. 1 it will be seen that partially shown record cards IP and 15 are identical and each have three decks of record columns; each column having seven index or code positions. The three decks are for convenience referred to and labelled as deck A, deck B, and deck C. Each deck has 60 columns and each column has the following seven card index positions: 5, 3, l, 0, Z, Y and X. The X, Y and Z positions are referred to as the zone positions; the 0, 1, 3 and 5 positions are referred to as the numeric positions.

One suitable coding arrangement of the numeric group is as follows: digit zero is represented by a punched hole in the "0 position; digit one is represented by a punched hole in the 1 position; digit two" is represented by a punched hole in the 0" and "1 positions; digit three is represented by a punched hole in the 3" position; digit four" is represented by punched holes in the 0 and 3" positions; digit five" is represented by a punched hole in the 5 position; digit six is repre sented by punched holes in the "0" and "5 positions; digit seven is represented by punched holes in the 0, 1" and "5 positions; digit eight" is represented by punched holes in the "3" and 5 positions; and digit "nine is represented by punched holes in the 0, 3" and "5 positions.

The following table discloses a suitable code for representing alphabetic and special character information:

Represented by punched holes Char 39131 i in the following positions A X, B X, 1 C X, 0, L D X, 3 E X, 0, 3 F X, 5 G X, 0, 5 H X, 0, 1, 5 I X, 3, 5 I X, 0, 3, 5 K Y, 0 L Y, 1 M Y, 0, 1 N Y, 3 O Y, 0, 3 P Y, 5 Q Y, 0, 5 R Y, 0, l, 5 S Y, 3, 5 T Y, 0, 3, 5 U Z, 0 V Z, l W Z, 0, 1 X Z, 3 Y Z, 0, 3 Z Z, 5 Special character Z, 0, Special character Z, 0, 1, 5 Special character Z, 3, 5 Special character Z, 0, 3, 5

Still referring to Fig. 1 it will be seen that the block diagram discloses schematically enclosed within broken line 2P a first or primary record card feed and sensing means; enclosed within broken line 28 a second or secondary record card feed and sensing means; and enclosed within broken line 2C a comparer circuit having a Right Entry High Indicator" and a Right Entry Low Indicator.

For purpose of explanation, let it now be assumed that record card 1P has a hole punched in the 3" position of the particular column in deck B that is being read by read brush 9P. Further, that the corresponding column of record card 1S has a punched hole in its 5" position. That is, in reading deck B, column 1 of record card 1P read brush 9P will read a punched "3 hole which represents the digit three," and in reading deck B column 1 of record card 15 read brush 98 will read a punched "5 hole representing the digit five."

The movement of record card 1P between contact roll F and read brush 9P is synchronized with the movement of record card 18 between contact roll 10S and read brush 98. Card lever contact 7P is closed whenever a primary record card is in position to be read. Card lever contact 7S is closed whenever a secondary record card is in position to be read. Cam contacts 3P and 5? make and break for each primary card index position (i.e., 5, 3, l, 0, Z, Y and X): at such times Within each card index position that when read brush 9? makes contact with contact roll 1GP through a punched hole, said read brush neither makes nor breaks the circuit completed. Cam contacts 38 and 5S serve a like function with respect to record card 18, contact roll 10S, and read brush 95.

When the selected column of primary record card IP is being read by read brush 9P, then the selected column of secondary record card 1S is being simultaneously read by read brush 9S. During card index time 3 of deck B a circuit is completed as follows: +40 volt source, cam contact 3?, lead 4P, cam contact 5P, lead 6P, card lever contact 7P, lead 8P, read brush 9P, contact roll 10F, contact brush llP, lead 12], and resistor 13F to ground. It will be noted that a portion of the potential impressed across resistor 13F when the afore-recited circuit is completed is transmitted via lead 14F to terminal 1C of comparer circuit 2C. The potential impressed on terminal 1C will be a positive pulse of a duration controlled by the making and breaking of cam contacts SP and SP, respectively, for card index position 3 of deck B. The duration of said pulse is not critical and will be somewhat less than card index time 3," where card index time 3 is defined as the time it takes card index position 3 of deck B to pass under the read brush. During card index time 5" of deck B the following circuit is com pleted and a positive voltage pulse is impressed via lead 148 on terminal 3C of comparer circuit 2C: +40 volt source, cam contacts 38, lead 48, cam contact 58, lead 68, card lever contact 78, lead 88, read brush 98, contact roll 10S, contact brush 11S, lead 125 and resistor 138 to ground. The comparer circuit 2C, shown in detail in Fig. 3, and explained in detail hereinafter, will by its Right Entry High Indicator manifest or indicate that the value read from column 1, deck B, of record card 1S is of higher order than the value read from column 1, deck B, of record card 1P, i.e., digit five as compared to digit three.

After the comparer circuit of Figs. 1 and 3 is disclosed in detail, hereinafter with reference to the embodiment of Fig. 2, it will be apparent to those skilled in the art how the device disclosed in Fig. 1 could be modified so that N columns of information in a first or primary record card could be compared with N columns of information in a second or secondary record card by utilizing a single comparer circuit, of the type represented by broken line 2C in Fig. 1 and shown in detail in Fig. 3.

6 THE EMBODIMENT SHOWN IN FIGS. 2 AND 3 Referring to Figs. 2 and 3 there is disclosed an embodiment accomplishing the comparing of data stored in five columns of record card 101P with data stored in the corresponding five columns of record card 1018. Record cards IMF and 1015 are of the same general type as record cards IP and 18 of Fig. 1. That is, record cards IMF and 1018 each have three decks: each deck having sixty columns, and each column having the following seven card index positions: 5, 3, 1, 0, Z, Y and X. The coding used with record cards 101P and 1018 is the same as that disclosed for use with record cards IP and 15 of Fig. 1.

From Fig. 2 it will be seen that record cards 101P and 1018 pass between their respective contact rolls and read brushes in synchronism with index point "5" of deck C being the leading edge.

Each of the ten identical emitters or commutators, namely, 61?, 621, 63F, 64F, 65F, 61S, 62S, 63S, 64S and 658, has its rotating arms, namely, 61PA, 62PA, 63PA, 64PA, 65PA, 618A, 628A, 638A, 648A and 65SA, connected to the following leads, respectively, SIP, 82F, 83F, 84F, 85F, 818, 828, 835, 848 and 858. Read brushes 91F, 92], 93F, 94F and 95? are respectively connected to leads 81P, 82F, 83F, 84F and 85P: read brushes 918, 928, 938, 948 and 95S are respectively connected to leads 81S, 82S, 838, 848 and 858.

Since the afore-recited ten cominutators of Fig. 2 are identical, function in exact synchronism, and each serves the very same function for a different read brush and write head, only a single commutator, namely 61?, will be disclosed in detail. commutator 611 has a contact arm 61PA which rotates at a fixed speed (counter-clockwise as viewed in Fig. 2) in synchronism with the passage of record cards IMF and 101S between their respective contact rolls and read brushes. Each commutator has seven conductive bars uniformly displaced about its commutator arm. Each commutator bar extends through an equal are. The seven commutator bars of each commutator are connected in common. Referring to Fig. 2 it will be seen that the seven commutator bars of commutator 61P are designated by reference characters 61P5, 61P3, 61P1, 61F), 61PZ, 61PY and 61PX Each commutator serves the function of making and breaking an electrical circuit which is completed only when its read brush makes contact with the contact roll.

Referring to Fig. 2, the two magnetic drums D1 and D2 each consist of a nommagnetic hub having a thinwalled cylinder of magnetic material overhanging the edge of the hub. It is to be appreciated that the thinwalled cylinder of magnetic material may consist of a non-ferrous material such as brass plated, on one or both sides, with a ferrous material such as nickel cobalt. Still referring to Fig. 2 it will be apparent that the hubs (not shown) respectively carry gears G4 and G1 as well as thin-walled cylinders of magnetic material PT and ST. Cylinders PT and ST are for convenience referred to as the primary magnetic track and secondary magnetic track."

Uniformly disposed about the periphery of the primary magnetic track PT are magnetic write heads PWl, PWZ, PW3, PW4 and PWS; these heads are for convenience referred to as the primary write heads. Uniformly disposed about the periphery of the second magnetic track ST are magnetic write" heads SW1, SW2, SW3, SW4 and SW5; these heads are for convenience referred to as the secondary write heads." Both the primary and secondary write heads are fixed in aligned position and have their respective air gaps very closely spaced or adjacent to their respective magnetic tracks, namely PT and ST.

Disposed within the primary magnetic track is read head RPl; disposed within the secondary magnetic track is read head RS1. Read heads RBI and RS1 are respectively mounted on members RPZ and RS2 which 7 are carried by shaft SH'Z. Shaft 81-12 is concentrically disposed with respect to magnetic drums D1 and D2, and rotates at a constant speed of 2880 r.p.m. in a clockwise direction as viewed in Fig. 2.

Shaft SHl has mounted thereon gears G3 and G2 which respectively mesh with gear G4 of magnetic drum D1, and gear G1 of magnetic drum D2. The gear ratio between gears G4 and G3 is the same as the gear ratio between gears G1 and G2. Shaft 51-11 is driven at a constant speed of such magnitude in a counterclockwise direction as viewed in Fig. 2, that drums D1 and D2 rotate in a clockwise direction at a uniform speed of 240 r.p.m.

In brief: the primary magnetic track and secondary magnetic track rotate in unison at a speed of 240 r.p.m. in a clockwise direction. The primary read head and secondary read head rotate in unison in a clockwise direction at a speed of 2880 r.p.m. The primary write heads and the secondary write heads are fixedly supported in predetermined aligned positions.

From Fig. 2 it will be seen that the air gap of the primary read head RPl is very closely or adjacently positioned to the internal surface of the primary magnetic track PT. One side of the winding of read head RPl is connected to shaft SH2. Shaft 81-12 is connected to ground through two parallel circuits, namely, brush RPS, lead 521 and lead 50?; and brush RS5, lead 528 and lead 508. The other side of the winding of read head RPl is connected to slip ring RPS, which is carried by and insulated from shaft 8H2. One side of cam contacts CB2 and CB6 are connected through lead 51 and brush RP4 to slip ring RP3.

The air gap of the secondary read head RS1 is very closely or adjacently positioned to the internal surface of the secondary magnetic track ST. One side of the winding of read head RS1 is connected to shaft 8H2. The other side of the winding of read head RS1 is com nected to slip ring RS3, which is carried by and insulated from shaft 8H2. One side of cam contacts CB4 and CB7 are connected through lead 515 and brush RS4 to slip ring RS3.

The recording field may be transverse, perpendicular or longitudinal with respect to the magnetic recording medium which in this instance is a magnetic track. The magnetic tracks PT and ST may be constructed of Cunife tape having a thickness of approximately .0015 inch and an effective width of approximately /32 Of an inch. The primary and secondary read and write heads may be of a design well known in the art.

Referring now to Fig. 3 the comparer circuit is shown in block diagram form. As set forth earlier herein the detailed circuits represented by each block in Fig. 3 are shown in Figs. 4A through 4H.

Again, referring to Fig. 3 contacts CCl, CC2, CC3, CC4 and CC5 may be of the cam type or the commutator type either of which are well known in the art. Fig. 3A discloses the timing of the above-recited contacts. The timing of cam contact CB8, shown in Fig. 3, is disclosed in Fig. 2A. The timing of cam contacts CB1, CB2, CB4, CB6 and CB7, respectively shown in Fig. 2, is, set forth in Fig. 2A.

In the circuit of Fig. 3, namely the comparcr circuit, relay coil R-l corresponds to the Right Entry Low Indicator" of Fig. l, and relay coil R-2 corresponds to the Right Entry High Indicator" of Fig. 1.

Record cards 101? and 1015 of Fig. 2 move at a uniform synchronized speed between their respective contacts rolls and read brushes. During the time that it takes for deck C of record card 10!? to pass between contact roll 119P and read brushes 91F through 95F and deck C of record card 101$ to pass between contact roll 1108 and read brushes 913 through 958, the arms of commutators 61? through 651 and 618 through 655 make one synchronized revolution. That is, during the time that card index position 5 of deck C of record cards 101P and 1015 are respectively being read the commutator arms 61PA through 65PA and 618A through 658A make and break contact respectively with the first segment of their respective commutators, i.e., the segment 61P5 of commutator 61F and corresponding segments of commutators 621 through 65? and 618 through 655. Likewise, during the reading of card index position 3 the commutator arms make and break contact with the second segment of their respective commutators, i.e., segment 61P3 of commutator 61F and the corresponding segments as to the remaining nine commutators. Each commutator has seven bars and each record card deck has seven positions, namely 5, 3, l, 0, Z, Y, and X. Each commutator arm makes and breaks with a commutator bar during the reading of each card index position of each deck.

The speed of rotation of drums D1 and D2 is 240 r.p.m. and said drums complete one-fifth of a revolution during the reading of one deck of record cards 101i and 1018 respectviely. There are five primary write heads uniformly disposed about the primary magnetic track PT. Each primary write head accomplishes the writing of magnetic pulses upon the primary magnetic track in accordance (i.e. spaced relationship) with the punched holes existing in the record card column corresponding thereto. That is, in one-fifth of a revolution of drum D1 five record card columns of information are written in serial by column order upon primary magnetic track PT. The same relationships, which will be more clear after the detailed examples set forth hereinafter, exist as to the secondary write heads and secondary track ST.

For convenience, let the primary and secondary magnetic tracks be respectively represented by thin-walled cylinders viewed from the left in Fig. 2. The primary and secondary magnetic tracks are then respectively shown in Figs. 5A and 6A.

From Fig. 5A it will be seen that the primary magnetic track is arbitrarily divided into five segments, each consisting of 72 mechanical degrees. The five segments of the primary magnetic track are labelled PCl, PC2, PC3, PC4 and PCS. Each segment has eight cells; each cell being capable of storing one magnetic bit of information. The eight cells of each segment are, for convenience, labelled as follows: 5, 3, l, 0, Z, Y, X and Segment PCl of the primary magnetic track accomplishes the storing of the information stored in the highest order column of the primary record card. Segment PC2 of the primary magnetic track accomplishes the storing of the information stored in the second highest order column of the primary record card. Segment PC3 of the primary magnetic track accomplishes the storing of the information stored in the third highest order column of the primary record card. Segment PC4 of the primary magnetic track accomplishes the storing of the information stored in the fourth highest order column of the primary record card. Segment PCS of the pnimary magnetic track accomplishes the storing of the information stored in the fifth highest order column of the primary record card. Segments SCI, 5C2, 5C3, 5C4 and SCS of the secondary magnetic track correspond respectively with segments PCl, PC2, PCS, PC4 and PCS of the primary magnetic track and perform a. like function with respect to the information obtained from the secondary record card.

Also, throughout, and the following examples in particular, a voltage pulse is a shift in voltage. The pulse is a positive pulse if the voltage shift is in a positive direction, regardless of the original and final voltage values. Likewise, a negative pulse represents a voltage shift in a negative direction, regardless of the original and final voltages values. The voltage change is the amplitude of the pulse.

Example No. I

From the following example the operation of the device disclosed in Figs. 2 and 3 will appear more clearly.

Merely for purpose of explanation let the following conditions be asssumed: The number represented by punched holes in the first five columns of deck B record card 101P is to be compared with the number represented by punched holes in the first five columns of deck B of record card 1015. The number represented by punched holes in the first five columns of deck B of primary record card 101P is 34967: the number represented by punched holes in the first five columns of deck B of secondary record card 1018 is 35132. Hence it follows that the first five columns of deck B of primary record card 101P have the following punched holes: column one the 3" position; column two the and 3 positions; column three the 0, 3 and positions; column four the 0 and 5 positions; and column five the 0, 1" and 5 positions. Further, it follows that the first five columns of deck B of secondary record card 1018 have the following punched holes: column one the 3 position; column two the 5" position; column three the 1 position; column four the 3" position; and column five the 0" and 1 positions.

Now referring to the timing chart shown in Fig. 2A, it is to be noted that during the first cycle point, namely machine time zero through nine degrees, card index position 5 of deck B of primary and secondary record cards 101P and 1018, respectively, pass beneath their respective read brushes and contact roll. Card index position 3 of deck B of primary and secondary record cards IMF and 1018 is read during machine time ten de grees through eighteen degrees; i.e., cycle point two. In like manner referring to deck B of primary and secondary record cards IMF and 1018, respectively: card index position 1 is read during machine time nineteen through twenty-seven degrees; card index position 0 is read during machine time twenty-eight through thirtysix degrees; card index position Z is read during machine time thirty-seven through forty-five degrees; card index position Y is read during machine time forty-six through fifty-four degrees; and card index position X is read during machine time fifty-five through sixty-three degrees. From a further inspection of the timing chart of Fig. 2A it will be seen that read-in cam CB1 is closed for the first eight cycle points, namely, the first seventytwo degrees of the machine cycle. That is, during readin time, drums D1 and D2 respectively rotate through seventy-two degrees, i.e., one-fifth of a revolution. It is to be recalled at this point that the primary and secondary wr-ite heads are stationary and are displaced each through an angle of seventy-two degrees about the periphery of their respective magnetic tracks.

From the legend appearing above Fig. 2A it will be apparent that while drums D1 and D2 make one complete revolution the read heads RPl and RS1 make twelve complete revolutions and the novel magnetic comparing device completes one complete cycle consisting of 360 degrees machine time. Hence if nine degrees of a machine cycle constitutes a cycle point then the device herein disclosed can be said to be a forty cycle point machine.

Read-in (Example N0. 1): During read in time, namely, machine time zero through seventy-two degrees the following sequence of operation takes place. As seen from Fig. 2A, cam contact CB1 closes at zero degrees and opens at seventy-two degrees machine time.

Read-in, card index position 5" of deck B: Now during the first machine cycle point, namely, zero through nine degrees, card index position 5 of deck B of primary and secondary record cards 101P and 1018, is read. Now it is to be recalled that in accordance with Example No. 1 there is a punched hole in the "5 position of the following columns: three, four and five of deck B of primary record card 101P; and two of deck B of secondary record card 1018. Therefore, during the reading of card index position 5 the following circuits are completed for a short interval of time: +40 volt source, lead 103, cam contact .CBl, lead 105, card lever contact 106,

lead 107, lead 108, contact brush illlP, contact roll 110P, read brush 93F, lead 83F, commutator arm 63PA, commutator bar 63P5, lead 73P, primary write head PW3, and lead 50F to ground: +40 volt source, lead 103, cam contact CB1, lead 105, card lever contact 106, lead 107, lead 108, contact brush lllP, contact roll 1 10P, read brush 94F, lead 84F, commutator arm 64PA, commutator bar 64P5, lead 74F, primary write head PW4, and lead 50? to ground: +40 volt source, lead 103, cam contact CB1, lead 105, card lever contact 106, lead 107, lead 108, contact brush 111P, contact roll 110P, read brush F, lead 85P, commutator arm 65PA, commutator bar 65P5, lead 75P, primary write head PWS and lead 50F to ground: and +40 volt source, lead 103, cam contact CB1, lead card lever contact 106, lead 107, lead 108, contact brush 1118, contact roll 1103, read brush 92S, lead 828, commutator arm 628A, commutator bar 6285, lead 728, secondary write head SW2, and lead 508 to ground. The above circuits are made for an interval of short duration within machine cycle point one, i.e., card index time 5, and result in primary write heads PW3, PW4, PW5 and secondary write head SW2, respectively, magnetizing small areas, i.e., storing magnetic bits on their respective magnetic tracks. From an inspection of Figs. 2 and 5A it will be apparent that the magnetic spots or bits written on primary magnetic track PT as a result of the punched "5 holes appearing in columns three, four and five of deck B of record card 101P, are displaced from each other by an angle of approximately seventy-two degrees. Further it is to be kept in mind that during machine cycle point one primary magnetic track PT and secondary magnetic track ST each rotate in unison through an angle of nine degrees machine time. Fig. 6A shows the bit stored in secondary magnetic track ST during cycle point one.

Read-in, card index position 3" of deck B: In accordance with Example No. 1 there is a punched 3" hole in the following columns: one, two and three of deck B of primary record card IMF; and one and four of deck B of secondary record card 1015. Now during the second machine cycle point, namely, ten through eighteen degrees machine time, card index position 3" of deck B of primary and secondary record cards IMF and 1018 is read. For a short duration, during the reading of card index position 3" a plurality of circuits corresponding to those set forth above in detail are completed. These circuits are respectively completed through primary write heads PWl, PW2 and PW3, and secondary Write heads SW1 and SW4. Due to the above circuits being completed for a short interval during read-in time 3 small discrete displaced areas of the primary magnetic and secondary magnetic track are magnetized. Reference is made to Figs. 5B and 6B of the drawings.

Read-in, card index position 1 of deck B: In accordance with Example N0. 1 there is a punched 1 hole in the following columns: five of primary record card 1011; and three and five of secondary record card 1018. During the third machine cycle point, namely, nineteen through twenty-seven degrees machine time, card index position "1 of deck B of primary and secondary record cards 101P and 1018 is read. For a short interval of time during the reading of card index position 1 the circuits are completed through primary write head PWS and secondary Write heads SW3 and SW5. Reference is made to Figs. 50 and 6C of the drawing.

Read-in, card index position 0" of Deck B: In conformity with Example No. 1 there is a punched hole in the "0 position of the following columns: two, three, four and five of deck B of primary record card 101?; and five of deck B of secondary record card 1018. Therefore, during the reading of card index position "0, namely, the fourth machine cycle point, i.e., twenty-eight through thirty-six degrees machine time, circuits are completed for a short interval of time through primary write 

